200521020 (1) 九、發明說明 【發明所屬之技術領域】 本發明係關於一種V型皮帶式連續可變傳動設備, 特別是可藉由電子致動器來控制傳動齒輪比例的 V型皮 帶式連續可變傳動設備。 【先前技術】 V型皮帶式連續可變傳動設備是早爲已知的,其中一 V型皮帶係延伸在一驅動滑輪與一從動滑輪之間,其中驅 動滑輪係連接至引擎等的原動機上而從動滑輪則連接至一 負載上,且 V型皮帶在驅動滑輪與從動滑輪上的纏繞直 徑係連續可變,以便能控制傳動齒輪比例。爲了改變 V 型皮帶的纏繞直徑,從一固定的滑輪部與一可動的滑輪部 之間,各形成驅動滑輪與從動滑輪,可動的滑輪部能夠在 一支撐軸的軸向上移動,以便能改變滑輪部之間的距離, 而因此改變纏繞直徑。 例如,在日本先行公開專利申請案第Hei 5-44827號 案中揭示一種連續可變傳動設備,其中可動滑輪部是藉由 一馬達來驅動。在此連續可變傳動設備中,驅動滑輪的可 動滑輪部經由一軸承而連接到一滑動桿上,且此滑動桿係 經由一齒輪而連接到一馬達上。 藉由從引擎轉速、節流閥的開啓量等來偵測引擎的操 作情形,便能執行傳動齒輪比例的控制。不管具有適當値 的傳動齒輪比例是否被偵測爲可動滑輪部的位置,且根據 -5- 200521020 (2) 所偵測出來的可動滑輪部位置而回饋控制馬達。 上述的連續可變傳動設備包括:一傳動箱,與一引擎 的曲柄箱形成一體且從曲柄箱形成一分隔壁;一傳動箱蓋 ,用以覆蓋傳動箱;及一外蓋,用以覆蓋傳動箱蓋。由於 外蓋能關閉冷卻用的空氣循環孔且在外觀的設計上相當重 要’傳動設備主要是由傳動箱與傳動箱蓋而保護。於是, 建構出一種傳動設備,其中滑動桿係經由一齒輪系統而連 接到一馬達上且藉由馬達而移動,以便控制傳動齒輪比例 ,使得這些零件能以一傳動箱蓋覆蓋起來。 然而,爲了形成傳動箱蓋來覆蓋齒輪系統與馬達,所 以必須整體地形成一複雜的結構。因此,製造用的模型將 會很複雜,且傳動箱的組裝過程也不容易。 【發明內容】 有鑒於上述先前技術中的缺點,本發明的目的是要提 供一種V型皮帶式連續可變傳動設備,其中設置有一馬 達及一齒輪系統,用以調整傳動齒輪比例,藉此能簡化傳 動箱的結構,且亦能簡化馬達、齒輪系統與蓋。 根據本發明的第一型態,V型皮帶式連續可變傳動設 備包括一由引擎驅動的驅動滑輪及一透過 V型皮帶由驅 動滑輪所驅動的從動滑輪。每個滑輪包括一固定部位及一 可動部位,其中固定部位係固定至一支撐軸,而可動部位 係用以相對於支撐軸在軸向上產生滑動,旦驅動滑輪的可 動部位被一馬達移動於軸方向上,以便改變固定部位與可 -6- 200521020 (3) 動部位之間的距離’且從動滑輪的可動部位可對應於此距 離的變化而滑動’以便藉此改囊從動滑輪相對於驅動滑輪 的轉速。V型皮帶式連續可變傳動設備的第一特徵在於它 包括:一齒輪系統’用以將馬達的動力傳送到驅動滑輪的 可動部位上;一傳動箱,用以容納驅動滑輪、從動滑輪與 其中的齒輪系統;一傳動箱蓋,係連接到傳動箱上,用以 覆蓋驅動滑輪與從動滑輪;及一致動器蓋,係連接至傳動 箱上’用以覆蓋齒輪系統。另外,特徵在於馬達係支撐在 致動器蓋上。 而且’根據本發明的第二型態,V型皮帶式連續可變 傳動設備的致動器蓋與傳動箱以合作方式一起形成一水泵 的壁面,用以將水循環至引擎。 而且,根據本發明的第三型態,V型皮帶式連續可變 傳動設備係用於一引擎上,此引擎具有一汽缸向前突出於 車輛上’且齒輪系統與馬達相對於驅動滑輪來說係設置在 汽缸的突出方向側上。 根據本發明的第四型態,自排機車(scooter )型的車 輛包括··乘客踏板’係設置在腳踏地板的後部上且位於車 體的正對兩側;一可變傳動設備,係插入在引擎與後輪之 間,其傳動比例可對應於致動器的操作而變化,其中致動 器係放置在乘客踏板的下方。 根據本發明的第五型態,自排機車型車輛的可變傳動 設備是一皮帶型傳動設備。此可變傳動設備與引擎一起合 作,該引擎的汽缸具有一大致水平的軸線,兩者形成一單 200521020 (4) 元擺動引擎’且致動器係放置在可變傳動設備之前方及汽 缸之側邊。 根據本發明的第六型態,自排機車型車輛的車體框架 設有一支撐框架’用以從下方支撐腳踏地板,且致動器係 放置在支撐框架的下方。 根據本發明的第七型態,自排機車型車輛的致動器是 一電動馬達,其在車體寬度方向上具有一旋轉軸。 根據上述本發明的第一型態,用以驅動傳動設備的驅 動'滑輪之驅動部位的馬達與齒輪系統,將其覆蓋的致動器 蓋係形成與傳動箱蓋不同的個別構件,其中傳動箱蓋係覆 蓋作爲傳動設備本體的皮帶設備。於是,就能簡化用於製 造蓋的模型之製作程序,而且當蓋在傳動箱上的組裝或拆 .卸之可工作性就會變得很好。 根據本發明的第二型態,由於也可以同時覆蓋水泵, 所以維修相當容易。 根據本發明的第三型態,在有汽缸突出的引擎中,可 以進行馬達與齒輪系統的配置,使其位於汽缸突出部的附 近。換句話說,可執行傳動設備的致動器機構之配置而不 會產生多餘的突出部位。 根據本發明的第四型態,將致動器放置在低於乘客踏 板的位置上有助於使自排機車型車輛的重心落在較低的位 置上。 根據本發明的第五型態,可藉由引擎的汽缸與可變傳 動設備來保護致動器。 -8- 200521020 (5) 根據本發明的第六型態,進一步可藉由高硬度的支撐 框架來有效地保護致動器。 而且’根據本發明的第七型態,致動器可以放置在引 擎汽缸的側邊,如此一來便不會從可變傳動設備的外側表 面向兩側突出去。 然而’要知道的是本發明的幾個實施例僅作爲說明之 用’對於熟知此項技術者來說,閱讀了以下的詳細說明之 後’在不背離本發明的精神與範圍之前提下,仍可以產生 出不同的變化與修改。 【實施方式】 以下,將伴隨附圖說明本發明的實施例。圖3是一側 視圖’顯示具有本發明一實施例的連續可變傳動設備之自 排型機車的外觀。參考圖3,自排型機車1的車體前部2 與車體後部3彼此之間係藉由一地板部4而連接在一起。 車體的骨架是由一下管6與一主管7所形成的,其中主管 係從下管6處向後向上延伸。一座位8係放置在主管7的 上方’放置安全帽用的一收納箱與油箱(兩者均未顯示) 係設置在座位8與主管7之間,座位8亦作爲收納箱的一 蓋。 下管6係在一前端上連接至車體前部2上所設置的一 頭管5,一前叉1 2係支撐在頭管5上用以產生樞轉移動 。手把11係裝配至前叉12的一上延伸部,而一前輪13 則是支撐在前叉1 2的一下端上用以旋轉。手把丨丨的上部 -9- 200521020 (6) 覆蓋有一手把蓋3 3,係亦作爲儀表板之用。 托架1 5係設置在主管7的筆直延伸部的一下端上, 且一吊掛托架1 8則經由一連桿構件1 6而連接到托架】5 上,且一擺動單元1 7係被支撐用以在托架1 5上產生滾動 。擺動單元7的後部與主管7的後部藉由一懸吊機構2 2 而彼此連接,其中該懸吊機構具有一吸震構件。在擺動單 元17的前部攜帶有一單汽缸四循環引擎200,V型皮帶 式連續可變傳動設備35與減速齒輪38係設置在引擎200 的後方。後輪21係連接至減速齒輪38的一輸出動力軸上 。換句話說,引擎200的輸出動力會經由連續可變傳動設 備3 5與減速齒輪3 8而傳送到後輪2 1上。 從引擎200的汽缸頭32延伸之一進氣管23係連接到 擺動單元1 7的一前部上。一汽化器24及連接到此汽化器 24上的空氣淸潔器25係放置在進氣管23上。停車用的 一主架26係支撐在吊掛托架18上,而吊掛托架又是設置 在擺動單元17的一曲柄箱31上。踢軸(kick shaft) 27 係從傳動設備3 5的一外蓋突起,且一踢臂2 8係固定至踢 軸27上,在踢臂28的一端上設有一踢板29。 圖1是一剖面圖’顯不連續可變傳動設備的一則部’ 且圖2是一剖面圖,顯示連續可變傳動設備的一後部。參 考圖1與2,連續可變傳動設備的外部輪廓包含一傳動箱 40、一傳動箱蓋401' —外蓋36及一致動器蓋58。傳動 箱40是引擎200的曲柄箱31之一部分。傳動箱蓋401從 車輛的左側覆蓋傳動箱4 0,而外蓋3 6進一步覆蓋傳動箱 -10- 200521020 (7) 蓋401。致動器蓋58係被組裝至傳動箱蓋401的一前部 (在車輛行進方向上的前部),且覆蓋一馬達57,其中 馬達係作爲致動器以便驅動傳動設備與齒輪系統60。 參考圖1,引擎200的曲柄軸41係藉由設置在傳動 箱40上的一軸承51以及另一個未顯示的軸承來支撐。突 出於傳動箱40外面的曲柄軸41之一部位43是用於驅動 滑輪45的一支撐軸,且是連續可變傳動設備的一驅動軸 〇 一導引管44係安裝在此部位(驅動軸)43的一外圍 上,驅動滑輪45包括一固定滑輪部451及一可動滑輪部 452,其中固定滑輪部係設置在驅動軸43的一端而可動滑 輪部係可在驅動軸43的軸向上移動。一 V型皮帶100係 延伸在上述的驅動滑輪45與從勸滑輪周圍之間。固定滑 輪部451係藉由將一螺帽46旋在驅動軸43的尾端之一螺 旋部上而固定至驅動軸43,可動滑輪部452的一輪轂453 的裝配方式能夠在導引管44的外圍上滑動,使得可動滑 輪部452能夠在驅動軸的方向上移動^ 在驅動軸43的軸向上呈細長的一細長孔或導引孔47 則形成在可動滑輪部452的輪轂453中。一導引銷48係 筆直地設置在導引管44的外圍上,且導引銷48的一頭部 481突出於導引孔47中。由碳氟樹脂製成具有低摩擦係 數的軸環49係設置在導引銷48的頭部上,使得它能覆蓋 住至少一部分的頭部,此頭部係正對著導引孔47的內表 面。最好,正對著導引管44外圍的導引銷48之頭部的一 -11 - 200521020 (8) 部分會受到此軸環4 9的覆蓋,如圖形中所示。因此,輪 轂45 3所固定的可動滑輪部452會藉由導引銷48而受到 限制而無法在相對於導引管44 (因此以及驅動軸43 )的 旋轉方向上移動,但僅可以相對於驅動軸4 3而在軸向上 移動。由於導引銷48可以軸環49插入其中的方式在輪轂 4 5 3的導引孔4 7中移動,所以可動滑輪部4 5 2的移動就 很平順且也可以抑制滑動噪音的產生。 一軸承固定環50係裝配至可動滑輪部4 52的輪轂 453外圍上,且一軸承51的內環係裝配至軸承固定環5〇 的外圍上。滑動桿用的一扣環5 2則是固定在軸承5 1的外 環上,而一滑動桿5 3則是裝配至扣環5 2上。滑動桿5 3 爲圓柱形且在其外側上具有一齒輪5 3 1,而一進給環5 4 則是裝配在滑動桿5 3的內側上。進給環5 4在其內圍上形 成有母螺紋,進給環5 4的母螺紋會與一管狀構件5 5的外 圍上形成之公螺紋卡合。管狀構件5 5藉由一螺栓5 6透過 焊接到其外圍的一凸緣部而固定至傳動箱4()上。 現在,將說明用以傳送動力到滑動桿5 3的齒輪5 3 1 之一驅動部。用於驅動滑動桿5 3的齒輪5 3 1之驅動部包 括一齒輪系統6 0與一馬達5 7。馬達5 7包括一底板5 7 1 及一外殼572。底板571係裝配且固定至傳動箱4〇的致 動器蓋上。一輸出動力齒輪591是形成於馬達軸59的一 端上。 齒輪系統60包括固定至一共同軸6]的第一級形齒輪 62與63,以及固定至另一共同軸的第二級形齒輪65與 -12- 200521020 (9) 66。齒輪系統60的齒輪最好是由樹脂製成,以便減少運 轉噪音。第一級形齒輪的軸6 ί係藉由設置在傳動箱40上 的一軸承67及設置在致動器蓋58上的另一軸承68而支 撐。同時,第二級形齒輪的軸64係藉由設置在傳動箱40 上的一軸承69及設置在致動器蓋58上的另一軸承70而 支撐。來自第一級形齒輪之間的大齒輪62會與輸出動力 齒輪591卡合,而小齒輪63會與來自第二級形齒輪之間 的大齒輪65卡合。來自第二齒輪之間的小齒輪66會與滑 動器53的齒輪531卡合。 齒輪641係形成在用於第二級形齒輪且通過軸承70 的軸64之一延伸部上,齒輪641是一蝸輪。此蝸輪641 會與一蝸輪卡合,該蝸輪係連接至作爲旋轉感測器的一旋 轉可變電阻或旋轉電位計上(旋轉感測器與蝸輪稍後將會 說明)。因此,軸64具有作爲感側器輸出軸的功能,以 便將齒輪系統6 0的旋轉量傳送到旋轉感測器上。 將一肋402形成在傳動箱40上,使得它能圍繞在滑 動桿53上形成的齒輪531之外圍,且一調節板72係藉由 一螺栓71而裝配到肋402的一尾端上,藉由此調節板72 可以限制滑動桿5 3到驅動滑輪4 5的移動。正常情形下, 滑動桿53的齒輪531僅能在不與調節板72產生接觸的範 圍內移動。 藉由上述結構,馬達5 7的旋轉可完全經由輸出動力 齒輪591、第一級形齒輪62,63以及第二級形齒輪65, 6 6而傳送至滑動桿5 3的齒輪5 3 1,以便能旋轉滑動桿5 3 -13· 200521020 (10) 。當滑動桿53旋轉時,進給環54能在管狀構件 旋轉’因此滑動桿5 3能在曲柄軸4 1的軸向上產生 給。藉由螺旋的作用所導致滑動桿5 3的移動方向 進給環5 4的母螺紋以及管狀構件5 5的公螺紋之方 〇 當滑動桿5 3沿著驅動軸4 3而移動時,此移動 軸承5 1而傳送至可動滑輪部452上,以便改變可 部4 5 2與固定滑輪部4 5 1之間的距離。假如介於固 部451與可動滑輪部452之間的距離增加的話,j 皮帶100會產生運轉而使得在驅動滑輪45上的纏 會連同從動滑輪的移動而減少。另一方面,在固定 451與可動滑輪部4 5 2之間的距離減少的方向上之 . 施加一部份的作用力,以便在驅動滑輪4 5的徑向 向上推擠V型皮帶100,如此會增加V型皮帶1〇〇 直徑以及從動滑輪的移動。 滑動桿5 3的位置可表示傳動設備的傳動齒輪 於是,可藉由上述用來偵測齒輪46 1的旋轉位置之 測器來偵測滑動感5 3的位置,且將偵測結果予以 控制傳動齒輪比例。 現在,將說明連續可變傳動設備的一後部之結 考圖,從動滑輪73包括一固定滑輪部731以及 滑輪部7 3 2。上面支撐有從動滑輪7 3的一從動軸 滑輪用的支撐軸)74係藉由軸承75, 76而支撐, 個軸承77裝配在從動軸74的一尾端側上,也就是 5 5周圍 .螺旋進 係根據 向而定 會透過 動滑輪 定滑輪 i!J v 型 繞直徑 滑輪部 力量會 朝外方 的纏繞 比例。 旋轉感 反饋來 構。參 一可動 (從動 將另一 在從動 -14- 78 200521020 (11) 軸74相對於軸承75的一左側部之一端上。將一軸環 裝配在從動軸74相對於軸承77的尖端側上,將一杯狀 合器板79焊接在此軸環78上。在從動軸74的尾端上 成一螺紋,而將一螺帽8 0旋在此螺紋上。軸環7 8與離 器板79透過軸承77的內環而固定到從動軸74上。一 承8 1係設置在從動軸74的一中間部之外圍上,且固定 輪部731的一輪轂82則藉由軸承81與軸承77而安裝 從動軸74的一外圍上。 而且,可動滑輪部732的一輪轂83係設置在固定 輪部731的輪轂82的外圍上,可動滑輪部732在從動 74的縱向中可相對於固定滑輪部731產生滑動式移動 導引銷84係筆直地設置在輪轂82上,設置在輪轂83 的導引孔831會與導引銷84的一頭部產生卡合,藉此 制可動滑輪部7 3 2相對於輪轂83的旋轉。 一離合器片支撐板85係藉由一螺帽86而固定在固 滑輪部731的輪轂82之一尾端部上,一離合器片87係 置在此支撐板85上。離合器片87係牢牢地安裝在具有 凸89的一臂90上,而此浮凸係藉由支撐板85上筆直 立的一樞軸88來支撐住以便旋轉。臂90藉由一彈簧 而在離合器片87遠離離合器板79的內環之方向上產生 壓。而且,將一線圈彈簧92插入可動滑輪部73 2與支 板85之間,且將可動滑輪部73 2壓迫朝向固定滑輪 731 側 ° 減速齒輪3 8係設置在連續可變傳動設備的一後部 離 形 合 軸 滑 在 滑 軸 〇 內 限 定 設 浮 豎 9 1 偏 撐 部 上 -15- 200521020 (12) 。減速齒輪38包括一輸入動力齒輪94、中間齒輪95,96 及一最終級形齒輪97。輸入齒輪94係設置在從動軸74 的另一端上,也就是在圖2所示的軸承75與76之間。輸 入動力齒輪94可從中間齒輪之間卡住大齒輪95,而同時 小齒輪96從中間齒輪之間卡住最終級形齒輪97。用於中 間齒輪95與96的軸係藉由軸承98與99而支撐,且用於 最終級形齒輪9 7 (就是輸出動力軸1 0 1 )的一軸則藉由軸 承102與103而支撐。軸承76,98與103則裝配在一殼 體4 03的一後部上,其中此殼體是輪轂402的後續部位, 同時軸承75,99與102係裝配在固定於殼體403上的一 減速齒輪蓋1〇4內。 將一感測器板105設置在固定滑輪部731的輪轂82 之一側面上,且將一磁性感測器1 06設置在正對著感測器 105的外圍上。感測器板105是由鐵製成,且由鐵製成的 感測器板1 〇 5在其外圍上具有一或多個凸起或凹陷部。於 是,磁性感測器1 〇6的輸出在每個形狀改變的部位會產生 變化,且例如可以從輸出變化之間的間隔而偵測出從動滑 輪73的轉速。磁性感測器1 06則固定至減速齒輪蓋1 04 上。 透過上述的結構,假如 V型皮帶的纏繞直徑在驅動 滑輪4 5側上增加的話,則V型皮帶1 〇 〇的張力也會增加 ,且此張力的增加會施加一股力量,而傾向增加介於從動 滑輪73的可動滑輪部73 2與固定滑輪部73 1之間的距離 。因此,在從動側上,V型皮帶1 00的纏繞直徑會減少。 -16- 200521020 (13) 換句話說,就是減少了減速齒輪比例。另一方面,假如V 型皮帶的纏繞直徑在驅動滑輪4 5側減少的話,則V型皮 帶1 〇〇的張力會減少。因此,假如線圈彈簧92的偏壓力 由於張力減少的緣故而超過施加到V型皮帶1 00的張力 之一分力的話,則會傾向施加一股力量,導致介於從動滑 輪7 3的可動滑輪部7 3 2與固定滑輪部7 3 1之間的距離產 生減少。因此,V型皮帶1 0 0的纏繞直徑在從動側上會增 加。換句話說,就是增加了減速齒輪比例。 當從動滑輪73的旋轉速度變得等於一預定値時,離 合器片87會由於離心力增加的緣故而與離合器板79接觸 。因此,連接到離合器板79上的從動軸74會產生旋轉, 進而透過輸出齒輪9 4、中間齒輪9 5,9 6及最終級形齒輪 97而旋轉輸出軸101。輸出動力軸101的旋轉會被傳送至 後輪2 1上,藉此使機車前進。 圖4是傳動箱40與致動器蓋5 8從車體左側看到的圖 形,參考圖4,傳動箱4 0與致動器蓋5 8沿著一卡合部i F 彼此卡合在一起。卡合部1 F包括一密封件(稍後說明) ,係設置在其上用於防水式地密封住卡合部1 F。根據以 下的詳細說明,卡合部1 F是由一垂直於圖形平面的平面 所形成的。傳動箱4 0與致動器蓋5 8的部位F與F1會形 成爲一共平面的表面,且傳動箱蓋401係裝配至這些部位 上,就是裝配在此共平面上。 … 圖5是致動器蓋58的一前視圖,且圖6是沿著圖5 的線A — A所作之剖面圖。致動器蓋5 8如同上述從馬達 -17- 200521020 (14) 5 7到軸64覆蓋住減速系統的零件,且亦作爲水泵用的蓋 ,其中水泵係經由引擎來循環冷卻水。參考圖5,致動器 蓋58上面形成有一管狀突起581,用以容納與齒輪641 卡合的一蝸輪110及此蝸輪110用的一軸111,其中此齒 輪係藉由裝配在支撐板85內的軸承70來支撐,並且此突 起還能支撐住此軸1 1 1。用於偵測蝸輪1 1 0的旋轉位置之 旋轉感測器1 1 2係連接到軸1 1 1上,此旋轉感測器1 1 2的 偵測輸出係供應至一未顯示的控制設備上,且透過與蝸輪 1 10連結操作的齒輪641,65,66與531,根據此輸出偵 測結果而偵測出可動滑輪部452的位置。 致動器蓋58具有浮凸582,583,用以固定馬達57 的基板5 7 1及座位5 8 5,5 8 6,其中這些座位係設置在一 浮凸孔5 84內,以便容納基板571的一輪轂。 而且,從圖6可以看出,感測器蓋5 8形成一水泵 113的外壁,可與傳動箱40的一部分產生合作。一推進 器Π 4及一軸1 1 5則是容納在此外壁圍繞的一空間內。軸 115係藉由一未顯示的傳動設備而連接至引擎上,且藉由 引擎的旋轉而驅動。一口環1 1 6是用以從散熱器經由一恆 溫器而循環的冷卻水之入口,而另一個口環1 1 7則是未通 過散熱器而循環的冷卻水之入口。在引擎開始時或當冷卻 水的溫度很低時,水會從口環1 1 7進入,但是假如冷卻水 的溫度高於一預定値時,則經過降溫的水則會從口環 U 6 經散熱器而進入。 圖7是一平面圖,顯示放置在傳動箱4 0與致動器蓋 -18- 200521020 (15) 5 8之間的一密封件,圖8是一側視圖,顯示此密封件的 主要部位,且圖9是此密封件—尾端部位。密封件1 20 具有:一環形部1 2 1,用以防水式地密封住水泵1 1 3 ; — 細長部,係從環形部1 2 1的一方向開始延伸;及另一個細 長部1 23,係從環形部1 2 1的另一個方向延伸。形成此密 封件1 2 0以便能在垂直於圖形平面的一方向上撓曲,如此 可保持一二維的平面,沿著此密封件,傳動箱40與致動 器蓋5 8能彼此防水式地卡合在一起。換句話說,從突起 124與125延伸出來到尾端部兩側上的部位127與128以 及介於突起124與125之間的細長部位122,這些部位在 形狀上是彼此不同的。特別是,雖然部位1 22具有圓形剖 面,使得它能裝配到一溝紋內,但是從突起124與125在 尾端部兩側上的部位1 2 7與1 2 8具有這樣的三維形狀,使 得他們能將致動器蓋5 8的一端面纏繞起來(參考圖8與 9 ) 〇 特別,密封件120的尾端部包括一箱形部128,係沿 著其一表面開啓,以便能覆蓋住致動器蓋5 8的尾端簿; 且又具有一部位129,用以箱形部128與突起124彼此連 接起來。一鉤部128a係設置在此箱形部128的一端上且 被纏繞在致動器蓋58的端面內。 圖I 〇是致動器的一後視圖,就是從傳動箱4 0看來的 致動器蓋之圖形;且圖1 1是沿著圖1 0的線B — B所作之 剖面圖。參考圖1 0,用於容納密封件1 2 0的一密封溝紋 大致上係沿著致動器蓋5 8的外部輪廓來形成。密封溝紋 -19- 200521020 (16) 1 3 0具有一容納密封件:! 2 〇的環形部之環形溝紋1 2 1以及 從環形溝紋1 3 1延伸的一細長溝紋1 3 2。而且,形成有兩 個引出部,其中一引出部133係用以將密封件120從局部 的環形溝紋1 3 1延伸到外側,而另一引出部1 3 4係用以將 密封件1 2 0從細長溝紋1 3 2延伸到外側。另外,分別將固 定密封件用的圓形凹穴1 35與1 36設置於引出部1 33與 1 3 4附近。 參考圖1 0與1 1,介於傳動箱4 0與致動器蓋5 8之間 的卡合部包括一傾斜部,就是平行於車體前後方向的一表 面F3(平行於上述F與F1的平面),且包括表面F4與 F5,係從表面F3在車輛的寬度上筆直豎立。在圖11中虛 線所指出的密封件1 2 0係沿著表面F 3與表面F 4,F 5放置 且分別被固定至圓形凹穴135,136內的中間部位之突 起124,125內。而且,在密封件120的一尾端部位上之 鉤部1 2 8 a則藉由致動器蓋5 8的一尾端表面溝紋5 8 a而捕 捉,藉由傳動箱蓋4 0 1來向下維持且固定住此鉤部1 2 8 a 〇 以此方式,本實施例的傳動設備除了包括密封機構之 外,係用於防水式地密封傳動箱4 0與傳動箱蓋4 0 1,特 別是用於防塵物體;還包括密封件1 2 0,係具有增強的密 封效果,以便維持防水性能。於是,可以在致動器蓋58 與傳動箱4 0之間提供適合水泵的密封條件,其中致動器 蓋與傳動箱是用於水泵的一壁面之構件。 圖1 2與1 3顯示本發明的第二實施例。特別是如圖 -20- 200521020 (17) 12所示,具有機車形式的車輛在其前端包括一車體框架F ;一前叉25,係可以支撐旋轉用的前輪WF ;及一頭管27 ,係用以支撐一駕駛手把2 6,此手把係連接至前叉2 5上 以便駕駛操作。一單元擺動引擎UE係於前後方向支撐在 車體框架F的一中間部上,以便作上下滾動,且在其一後 端支撐一旋轉用的後輪WR。從側視圖看來呈上下細長的 一油箱2 8及放置在此油箱2 8後方的一散熱器2 9,均被 設置在車體框架F上且在單元擺動引擎UE的前面。將一 容納箱3 0裝配至車體框架F上,使得它能從上方覆蓋住 單元擺動引擎,且前後排列形式的駕駛座椅3 1則設置在 容納箱30上,而具有一前座32與一後座33。而且,由 合成樹脂製成的車體蓋34係裝配至車體框架F上,且覆 蓋住車體框架F、單元擺動引擎UE的一前部、散熱器29 與容納箱30。 參考圖13,單元擺動引擎UE,包括一氣冷式引擎E ,具有大致水平延伸的汽缸軸;且包括一皮帶式可變傳動 設備Μ,具有一傳動皮帶與一滑輪,以可變速度將引擎e 的輸出動力傳送至後輪WR上。可變傳動設備Μ能驅動 曲柄軸側上的一可動滑輪,以便對應於作爲致動器的一電 ? ’^〜 動馬達42之操作,而改變傳動齒輪比例。 可變傳動設備Μ的一傳動箱93係連續地設置到引擎 Ε的曲柄箱4 4之左側上,使得它會從引擎Ε增大到左側 ,且延伸到後輪WR的左側上。一擺動臂4 8係在其一前 辆部上連接到曲柄相4 4的右側上’且後輪W R係支撐用 -21 - 200521020 (18) 以在傳動箱93的後端部與擺動臂48的後端部之間旋轉。 附帶一提,用於改變速度的電動馬達(致動器)42 係放置在引擎E的汽缸4 5的左側上而在可變傳動設備Μ 的前面,且裝配在傳動箱93的前向突起93a上,使得其 一軸線被定向於車體的寬度方向。此外,從側面看來,電 動馬達42係放置在一左側乘客踏板1 62的下方而介於一 對左右乘客踏板162之間,係設置在車體蓋34上而在形 成部份車體框架F的兩個支撐框架4 1之間的左側支撐框 架41下方。 雖然已經藉由上述實施例來說明本發明,但把發明仍 可以不同方式來變化。這樣的變化並未脫離本發明的精神 與範圍,且對於熟知此技術者來說,這類的修改均涵蓋於 以下的申請專利範圍所定義的範圍內。 【圖式簡單說明】 圖1是一剖面圖,顯示本發明第一實施例之皮帶式連 續可變傳動設備的一前部; 圖2是一剖面圖’顯示本發明第一實施例之皮帶式連 續可變傳動設備的一後部; 圖3是一側視圖,顯示本發明第一實施例的機車; 圖4是一前視圖,顯示傳動箱與致動器蓋; 圖5是一前視圖’顯示設置在連續可變傳動設備的前 部之一齒輪單元蓋; 圖6是一剖面圖’顯示由致動器蓋與傳動箱所形成的 -22- 200521020 (19) 一水泵之一壁部; 圖7是一密封件的平面圖; 圖8是一側視圖,顯示密封件的主要部位; 圖9是一放大圖,顯示密封件的一端部; 圖1 〇是致動器蓋的一後視圖; 圖1 1是沿著圖10的線B-B所作之剖面圖; 圖1 2是一左側視圖,顯示本發明第二實施例之自排 機車;且 圖13顯示在圖12中的自排機車的單元擺動引擎、連 續可變傳動設備及後輪之間的相對配置情形。 【主要元件符號說明】 1 :機車 2 :車體前部 3 :車體後部 4 :地板部 5 :頭管 6 :下管 7 :主管 8 :座位 1 1 :手把 1 2 :前叉 I 3 :前輪 1 5 :托架 •23- 200521020 (20) 1 6 :連桿構件 1 7 :擺動單元 1 8 :吊掛托架 2 1 :後輪 22 :懸吊機構 23 :進氣管 24 :汽化器 26 :主架 27 :踢軸 2 8 :油箱 29 :散熱器 3 0 :容納箱 3 1 :曲柄箱 32 :前座 3 3 :後座 3 5 : V型皮帶式連續可變傳動設備 3 6 :外蓋 3 8 :減速齒輪 4 0 :傳動箱 4 1 :曲柄軸 4 2 :電動馬達 4 3 :驅動軸 44 :導引管 4 5 :驅動滑輪 -24- 200521020 (21) 47 :導引孔 48 :導引銷 4 9 :軸環 5 0 :軸承固持環 51 :軸承 5 2 :扣環 5 3 :滑動桿 5 4 :進給環 5 5 :管狀構件 5 6 :螺栓 5 7 :馬達 5 8 :致動器蓋 5 8 a :端面溝紋 5 9 :馬達軸 6 0 :齒輪系統 6 2,6 3 :第一級形齒輪 6 1,6 4 :共同軸 6 5,6 6 :第二級形齒輪 67, 68, 69, 70:軸承 7 1 :螺栓 72 :調整板 73 :從動滑輪 74 :從動軸 75, 76, 77, 8]:軸承 -25- 200521020 (22) 7 8 :軸環 79 :杯狀離合器板 8 2,8 3 :輪穀 8 0,8 6 ’·螺帽 8 5 :離合器片支撐板 8 7 :離合器片 8 8 :樞軸 8 9 :浮凸 90 :臂 91 :彈簧 92 :線圈彈簧 9 3 :傳動箱 9 3 a :前向突起 94 :輸入動力齒輪 9 5,9 6 :中間齒輪 9 7 :最終級型齒輪 98, 99, 102, 103:軸承 1 00 : V型皮帶 1 0 1 :輸出動力軸 105 :感測器板 ]06 :磁性感測器 1 1 0 :蝸輪 1 η :軸 1 1 2 :旋轉感測器 -26- 200521020 (23) 1 1 3 :水泵 1 14 :推進器 1 1 5 :軸 1 1 6,1 1 7 : 口環 1 2 0 :座位 1 2 1 :環狀部 1 2 2,1 2 3 :細長部 1 24,1 25 :突起 127, 128, 129 :部位 1 2 8 a :鉤部 1 3 0 :密封溝紋 131 :環狀溝紋 1 3 2 :細長溝紋 1 33,1 34 :引出部 135,136:圓形凹穴 1 62 :左側乘客踏板 2 00 :弓丨擎 401 :傳動箱蓋 4 02 ··肋 403 :殼體 4 5 1 :固定滑輪部 45 2 :可動滑輪部 4 5 3 :輪轂 4 8 ] ··頭部 -27- 200521020 (24) 53 1: 571 : 5 72 : 5 8 1: 5 82, 5 84 : 5 8 5, 591 : 641 : 73 1: 7 3 2 : 齒輪 底板 外殼 管狀突起 5 8 3 :浮凸 浮凸孔 5 8 6 :座位 輸出動力齒輪 齒輪 固定滑輪部 可動滑輪部 -28-200521020 (1) IX. Description of the invention [Technical field to which the invention belongs] The present invention relates to a V-belt type continuously variable transmission device, and in particular, a V-belt type continuous control of a transmission gear ratio by an electronic actuator Variable transmission equipment. [Prior technology] V-belt type continuously variable transmission equipment has been known for a long time. A V-belt system extends between a driving pulley and a driven pulley, and the driving pulley system is connected to the prime mover of the engine and the like. The driven pulley is connected to a load, and the winding diameter of the V-belt on the driving pulley and the driven pulley is continuously variable in order to control the ratio of the transmission gear. In order to change the winding diameter of the V-belt, a driving pulley and a driven pulley are formed between a fixed pulley portion and a movable pulley portion. The movable pulley portion can move in the axial direction of a support shaft so that the pulley can be changed. The distance between the parts and thus the winding diameter is changed. For example, Japanese Patent Application Laid-Open No. Hei 5-44827 discloses a continuously variable transmission device in which a movable pulley portion is driven by a motor. In this continuously variable transmission device, the movable pulley portion of the driving pulley is connected to a sliding rod via a bearing, and the sliding rod is connected to a motor via a gear. By detecting the operation of the engine from the engine speed, the opening amount of the throttle valve, etc., the control of the transmission gear ratio can be performed. Regardless of whether the ratio of the transmission gear with an appropriate 値 is detected as the position of the movable pulley portion, and the control motor is fed back based on the position of the movable pulley portion detected in -5- 200521020 (2). The above-mentioned continuously variable transmission equipment includes: a transmission case that is integrated with an engine crank case and forms a partition wall from the crank case; a transmission case cover to cover the transmission case; and an outer cover to cover the transmission Box cover. Because the outer cover can close the cooling air circulation holes and is quite important in the design of the appearance, the transmission equipment is mainly protected by the transmission case and the transmission case cover. Thus, a transmission device is constructed in which the sliding rod system is connected to a motor via a gear system and is moved by the motor in order to control the transmission gear ratio so that these parts can be covered by a transmission case cover. However, in order to form the transmission case cover to cover the gear system and the motor, a complicated structure must be integrally formed. Therefore, the manufacturing model will be complicated, and the assembly process of the transmission case will not be easy. [Summary of the Invention] In view of the above-mentioned shortcomings in the prior art, an object of the present invention is to provide a V-belt type continuously variable transmission device, in which a motor and a gear system are provided for adjusting the ratio of transmission gears, thereby enabling Simplify the structure of the transmission box, and also simplify the motor, gear system and cover. According to a first aspect of the present invention, the V-belt type continuously variable transmission device includes a driving pulley driven by an engine and a driven pulley driven by the driving pulley through a V-belt. Each pulley includes a fixed portion and a movable portion, wherein the fixed portion is fixed to a support shaft, and the movable portion is used to generate axial sliding relative to the support shaft. Once the movable portion of the driving pulley is moved to the shaft by a motor Direction, in order to change the distance between the fixed part and the movable part-6-200521020 (3) The movable part of the driven pulley can slide in response to the change of this distance, so as to change the capsule driven pulley relative to the driving pulley Speed. The first characteristic of the V-belt type continuously variable transmission device is that it includes: a gear system 'for transmitting the power of the motor to the movable part of the driving pulley; and a transmission box for accommodating the driving pulley, the driven pulley and the inside thereof. A gear box cover; a gear box cover connected to the gear box to cover the driving pulley and a driven pulley; and an actuator cover connected to the gear box to cover the gear system. It is also characterized in that the motor is supported on the actuator cover. Moreover, according to the second aspect of the present invention, the actuator cover of the V-belt type continuously variable transmission device cooperates with the transmission case to form a wall surface of a water pump for circulating water to the engine. Moreover, according to a third aspect of the present invention, a V-belt type continuously variable transmission device is used on an engine having a cylinder protruding forward from the vehicle 'and the gear system and the motor relative to the driving pulley It is provided on the protruding direction side of the cylinder. According to a fourth aspect of the present invention, a scooter type vehicle includes a passenger pedal, which is disposed on the rear of the foot floor and is located on both sides of the vehicle body; a variable transmission device, Inserted between the engine and the rear wheel, its transmission ratio can be changed corresponding to the operation of the actuator, where the actuator is placed under the passenger pedal. According to a fifth aspect of the present invention, the variable transmission device of a vehicle of a self-propelled vehicle type is a belt type transmission device. This variable transmission device cooperates with the engine. The cylinder of the engine has a substantially horizontal axis, and the two form a single 200521020 (4) element swing engine. The actuator is placed in front of the variable transmission device and the cylinder. Side. According to a sixth aspect of the present invention, the body frame of a self-propelled vehicle is provided with a support frame 'for supporting the foot floor from below, and the actuator is placed below the support frame. According to a seventh aspect of the present invention, the actuator of a self-propelled vehicle is an electric motor having a rotating shaft in a width direction of the vehicle body. According to the above-mentioned first aspect of the present invention, the motor and gear system used to drive the driving part of the driving pulley of the transmission device, and the actuator cover covered by it forms a separate component from the transmission case cover, wherein the transmission case The cover covers the belt device as the transmission device body. Therefore, the manufacturing process of the model for making the cover can be simplified, and the workability when the cover is assembled or disassembled on the transmission case becomes good. According to the second aspect of the present invention, since the water pump can also be covered at the same time, maintenance is relatively easy. According to a third aspect of the present invention, in an engine with a cylinder protrusion, the motor and the gear system can be arranged so as to be located near the cylinder protrusion. In other words, the configuration of the actuator mechanism of the transmission device can be performed without generating an excessive protrusion. According to a fourth aspect of the present invention, placing the actuator at a position lower than the passenger's pedal helps to lower the center of gravity of the vehicle of the self-propelled vehicle type to a lower position. According to a fifth aspect of the present invention, the actuator can be protected by the cylinder of the engine and the variable transmission device. -8- 200521020 (5) According to the sixth aspect of the present invention, the actuator can be effectively protected by a highly rigid support frame. Moreover, according to the seventh aspect of the present invention, the actuator can be placed on the side of the engine cylinder so that it does not protrude from both sides of the outer surface of the variable transmission device. However, "It is to be understood that several embodiments of the present invention are for illustration purposes only." For those skilled in the art, after reading the following detailed description, "is mentioned without departing from the spirit and scope of the present invention. Can produce different changes and modifications. [Embodiment] Hereinafter, embodiments of the present invention will be described with reference to the drawings. Fig. 3 is a side view 'showing the appearance of a self-propelled locomotive having a continuously variable transmission device according to an embodiment of the present invention. Referring to FIG. 3, the front body portion 2 and the rear body portion 3 of the self-propelled locomotive 1 are connected to each other through a floor portion 4. The skeleton of the vehicle body is formed by the lower pipe 6 and a main pipe 7, wherein the main pipe extends backward and upward from the lower pipe 6. A seat 8 is placed above the main pipe 7 and a storage box and a fuel tank (both not shown) for a hard hat are placed between the seat 8 and the main pipe 7. The seat 8 also serves as a cover of the storage box. The lower tube 6 is connected at a front end to a head tube 5 provided on the front part 2 of the vehicle body, and a front fork 12 is supported on the head tube 5 to generate a pivoting movement. The handlebar 11 is assembled to an upper extension of the front fork 12, and a front wheel 13 is supported on the lower end of the front fork 12 for rotation. The upper part of the handlebar 丨 丨 -9- 200521020 (6) is covered with a handlebar cover 3 3, which is also used as an instrument panel. The bracket 15 is provided on the lower end of the straight extension of the main pipe 7, and a hanging bracket 18 is connected to the bracket through a link member 16], and a swing unit 17 is It is supported to produce rolling on the bracket 15. The rear part of the swing unit 7 and the rear part of the main pipe 7 are connected to each other by a suspension mechanism 2 2, wherein the suspension mechanism has a shock-absorbing member. A single-cylinder four-cycle engine 200 is carried at the front of the swing unit 17, and a V-belt type continuously variable transmission device 35 and a reduction gear 38 are arranged behind the engine 200. The rear wheel 21 is connected to an output power shaft of the reduction gear 38. In other words, the output power of the engine 200 is transmitted to the rear wheels 21 through the continuously variable transmission device 35 and the reduction gear 38. An intake pipe 23 extending from a cylinder head 32 of the engine 200 is connected to a front portion of the swing unit 17. A carburetor 24 and an air cleaner 25 connected to the carburetor 24 are placed on the intake pipe 23. A main frame 26 for parking is supported on a suspension bracket 18, and the suspension bracket is provided on a crank case 31 of the swing unit 17. A kick shaft 27 protrudes from an outer cover of the transmission device 35, and a kick arm 28 is fixed to the kick shaft 27. A kick plate 29 is provided on one end of the kick arm 28. Fig. 1 is a sectional view 'showing a section of a discontinuously variable transmission device' and Fig. 2 is a sectional view showing a rear portion of the continuously variable transmission device. 1 and 2, the outer contour of the continuously variable transmission device includes a transmission case 40, a transmission case cover 401'-outer cover 36, and an actuator cover 58. The transmission case 40 is a part of the crank case 31 of the engine 200. The gearbox cover 401 covers the gearbox 40 from the left side of the vehicle, and the outer cover 36 covers the gearbox -10- 200521020 (7) cover 401 further. The actuator cover 58 is assembled to a front portion of the transmission case cover 401 (front portion in the direction of travel of the vehicle), and covers a motor 57 that serves as an actuator to drive the transmission device and the gear system 60. Referring to FIG. 1, the crank shaft 41 of the engine 200 is supported by a bearing 51 provided on the transmission case 40 and another bearing not shown. One part 43 of the crank shaft 41 protruding outside the transmission case 40 is a support shaft for driving the pulley 45, and is a drive shaft of the continuously variable transmission device. A guide pipe 44 is installed at this part (the drive shaft 43) On one periphery of the driving pulley 45, the driving pulley 45 includes a fixed pulley portion 451 and a movable pulley portion 452. The fixed pulley portion is disposed at one end of the driving shaft 43 and the movable pulley portion is movable in the axial direction of the driving shaft 43. A V-belt 100 extends between the driving pulley 45 and the periphery of the driving pulley 45 described above. The fixed pulley portion 451 is fixed to the drive shaft 43 by screwing a nut 46 on a screw portion of a trailing end of the drive shaft 43. The assembly manner of a hub 453 of the movable pulley portion 452 can be Sliding on the periphery allows the movable pulley portion 452 to move in the direction of the drive shaft ^ An elongated hole or guide hole 47 that is elongated in the axial direction of the drive shaft 43 is formed in the hub 453 of the movable pulley portion 452. A guide pin 48 is provided straight on the periphery of the guide tube 44 and a head 481 of the guide pin 48 protrudes into the guide hole 47. A collar 49 made of fluorocarbon resin with a low coefficient of friction is provided on the head of the guide pin 48 so that it can cover at least a part of the head, which is directly opposite the inside of the guide hole 47 surface. Preferably, a part -11-200521020 (8) of the head of the guide pin 48 facing the periphery of the guide tube 44 will be covered by this collar 49, as shown in the figure. Therefore, the movable pulley portion 452 fixed by the hub 45 3 is restricted by the guide pin 48 and cannot move in the rotation direction with respect to the guide tube 44 (and therefore the drive shaft 43), but only with respect to the drive The shaft 4 3 moves in the axial direction. Since the guide pin 48 can be moved in the guide hole 47 of the hub 4 5 3 with the collar 49 inserted therein, the movement of the movable pulley portion 4 5 2 is smooth and the generation of sliding noise can be suppressed. A bearing fixing ring 50 is fitted to the periphery of the hub 453 of the movable pulley part 4 52, and an inner ring of a bearing 51 is fitted to the periphery of the bearing fixing ring 50. A retaining ring 5 2 for the sliding rod is fixed to the outer ring of the bearing 51, and a sliding rod 5 3 is assembled to the retaining ring 5 2. The slide lever 5 3 is cylindrical and has a gear 5 3 1 on its outer side, and a feed ring 5 4 is assembled on the inner side of the slide lever 5 3. The feed ring 54 is formed with a female thread on its inner periphery, and the female thread of the feed ring 54 is engaged with a male thread formed on the outer periphery of a tubular member 55. The tubular member 55 is fixed to the transmission case 4 () by a bolt 5 6 through a flange portion welded to its periphery. Now, a driving portion of one of the gears 5 3 1 for transmitting power to the slide lever 5 3 will be described. The driving part of the gear 5 3 1 for driving the slide lever 5 3 includes a gear system 60 and a motor 57. The motor 5 7 includes a bottom plate 5 7 1 and a casing 572. The bottom plate 571 is assembled and fixed to the actuator cover of the transmission case 40. An output power gear 591 is formed on one end of the motor shaft 59. The gear system 60 includes first stage gears 62 and 63 fixed to one common shaft 6], and second stage gears 65 and -12-200521020 (9) 66 fixed to another common shaft. The gears of the gear system 60 are preferably made of resin so as to reduce operating noise. The shaft 6 of the first stage gear is supported by a bearing 67 provided on the transmission case 40 and another bearing 68 provided on the actuator cover 58. At the same time, the shaft 64 of the second-stage gear is supported by a bearing 69 provided on the transmission case 40 and another bearing 70 provided on the actuator cover 58. The large gear 62 from between the first stage gears is engaged with the output power gear 591, and the small gear 63 is engaged with the large gear 65 from between the second stage gears. The pinion 66 from the second gear is engaged with the gear 531 of the slider 53. A gear 641 is formed on one of the extensions of the shaft 64 for the second-stage gear through the bearing 70. The gear 641 is a worm gear. The worm gear 641 is engaged with a worm gear, which is connected to a rotary variable resistor or a rotary potentiometer as a rotation sensor (the rotation sensor and the worm gear will be described later). Therefore, the shaft 64 has a function as an output shaft of the side sensor to transmit the rotation amount of the gear system 60 to the rotation sensor. A rib 402 is formed on the transmission case 40 so that it can surround the periphery of the gear 531 formed on the sliding rod 53, and an adjusting plate 72 is fitted to a tail end of the rib 402 by a bolt 71. Thereby, the adjustment plate 72 can restrict the movement of the sliding lever 53 to the driving pulley 45. Under normal circumstances, the gear 531 of the slide lever 53 can only move within a range that does not come into contact with the adjustment plate 72. With the above structure, the rotation of the motor 57 can be completely transmitted to the gear 5 3 1 of the slide lever 5 3 through the output power gear 591, the first stage gears 62, 63, and the second stage gears 65, 6 6 so that Can rotate the slide bar 5 3 -13 · 200521020 (10). When the slide lever 53 rotates, the feed ring 54 can rotate on the tubular member 'so that the slide lever 53 can be fed in the axial direction of the crank shaft 41. The movement direction of the sliding rod 5 3 caused by the action of the screw is the square of the female thread of the feed ring 5 4 and the male thread of the tubular member 55. When the sliding rod 5 3 moves along the driving shaft 4 3, this movement The bearing 51 is transmitted to the movable pulley portion 452 so as to change the distance between the movable portion 4 5 2 and the fixed pulley portion 4 5 1. If the distance between the fixed portion 451 and the movable pulley portion 452 is increased, the j-belt 100 will run and the entanglement on the driving pulley 45 will be reduced together with the movement of the driven pulley. On the other hand, in a direction in which the distance between the fixed 451 and the movable pulley portion 4 5 2 decreases. A part of force is applied to push the V-belt 100 upward in the radial direction of the driving pulley 45, and so on Will increase the 100 diameter of the V-belt and the movement of the driven pulley. The position of the sliding lever 5 3 can indicate the transmission gear of the transmission device. Therefore, the position of the sliding sense 5 3 can be detected by the above-mentioned measuring device for detecting the rotation position of the gear 46 1, and the detection result is controlled for transmission. Gear ratio. Now, a diagram of a rear portion of the continuously variable transmission device will be described. The driven pulley 73 includes a fixed pulley portion 731 and a pulley portion 7 3 2. A driven shaft (support shaft for a driven shaft pulley) 74 on which the driven pulley 7 3 is supported is supported by bearings 75, 76, and a bearing 77 is mounted on a tail end side of the driven shaft 74, that is, around 5 5 The spiral feed is determined by the direction of the winding ratio of the pulley around the diameter of the pulley by the moving pulley fixed pulley i! J v. Rotary feedback to construct. Partially movable (the driven one is on the other side of the driven 14-78 200521020 (11) one end of the left side of the shaft 74 with respect to the bearing 75. A collar is fitted on the tip side of the driven shaft 74 with respect to the bearing 77 A cup-shaped coupler plate 79 is welded to this collar 78. A thread is formed on the trailing end of the driven shaft 74, and a nut 80 is screwed onto this thread. The collar 78 and the separator plate 79 is fixed to the driven shaft 74 through the inner ring of the bearing 77. A bearing 81 is provided on the periphery of a middle portion of the driven shaft 74, and a hub 82 of the fixed wheel portion 731 is supported by the bearing 81 and A bearing 77 is mounted on one periphery of the driven shaft 74. Further, a hub 83 of the movable pulley portion 732 is provided on the periphery of the hub 82 of the fixed pulley portion 731, and the movable pulley portion 732 can be opposed to each other in the longitudinal direction of the driven 74 A sliding-type moving guide pin 84 generated at the fixed pulley portion 731 is provided straight on the hub 82, and a guide hole 831 provided in the hub 83 is engaged with a head of the guide pin 84, thereby manufacturing a movable pulley. The rotation of the portion 7 3 2 relative to the hub 83. A clutch plate support plate 85 is fixed to the fixed pulley portion 7 by a nut 86. At the rear end of one of the hubs 82 of 31, a clutch plate 87 is attached to this support plate 85. The clutch plate 87 is firmly attached to an arm 90 having a projection 89, and the embossment is supported by An upright pivot 88 is supported on the plate 85 for rotation. The arm 90 generates a pressure in the direction of the clutch plate 87 away from the inner ring of the clutch plate 79 by a spring. Furthermore, a coil spring 92 is inserted into the movable pulley Between the portion 73 2 and the support plate 85, the movable pulley portion 73 2 is pressed toward the fixed pulley 731 side. The reduction gear 3 8 is provided on a rear part of the continuously variable transmission device. Set the floating vertical 9 1 -15- 200521020 (12). The reduction gear 38 includes an input power gear 94, intermediate gears 95, 96, and a final stage gear 97. The input gear 94 is provided on the driven shaft 74. On the other end, that is, between the bearings 75 and 76 shown in Figure 2. The input power gear 94 can hold the large gear 95 from between the intermediate gears, while the small gear 96 can lock the final stage from between the intermediate gears. Gear 97. Shaft system for intermediate gears 95 and 96 Supported by bearings 98 and 99, and a shaft for the final stage gear 9 7 (that is, the output power shaft 1 0 1) is supported by bearings 102 and 103. Bearings 76, 98, and 103 are assembled in a housing A rear part of the 04 03, where the housing is a subsequent part of the hub 402, and bearings 75, 99, and 102 are assembled in a reduction gear cover 104 fixed to the housing 403. A sensor board 105 is disposed on one side of the hub 82 of the fixed pulley portion 731, and a magnetic sensor 106 is disposed on the periphery of the sensor 105. The sensor plate 105 is made of iron, and the sensor plate 105 made of iron has one or more protrusions or depressions on its periphery. Therefore, the output of the magnetic sensor 10 is changed at each part where the shape changes, and the rotation speed of the driven pulley 73 can be detected from the interval between the output changes, for example. The magnetic sensor 1 06 is fixed to the reduction gear cover 1 04. Through the above structure, if the winding diameter of the V-belt is increased on the driving pulley 45 side, the tension of the V-belt 100 will also increase, and the increase of this tension will exert a force, which tends to increase the media. The distance between the movable pulley portion 73 2 of the driven pulley 73 and the fixed pulley portion 73 1. Therefore, the winding diameter of the V-belt 100 on the driven side is reduced. -16- 200521020 (13) In other words, the reduction gear ratio is reduced. On the other hand, if the winding diameter of the V-belt is reduced on the driving pulley 45 side, the tension of the V-belt 100 will decrease. Therefore, if the biasing force of the coil spring 92 exceeds a force of one part of the tension applied to the V-belt 100 due to the reduced tension, a force will tend to be applied, resulting in the movable pulley portion between the driven pulleys 73. The distance between 7 3 2 and the fixed pulley portion 7 3 1 is reduced. Therefore, the winding diameter of the V-belt 100 increases on the driven side. In other words, the reduction gear ratio is increased. When the rotation speed of the driven pulley 73 becomes equal to a predetermined speed, the clutch plate 87 comes into contact with the clutch plate 79 due to an increase in centrifugal force. Therefore, the driven shaft 74 connected to the clutch plate 79 rotates, and further, the output shaft 101 is rotated through the output gear 94, the intermediate gears 95, 96, and the final stage gear 97. The rotation of the output power shaft 101 is transmitted to the rear wheels 21, thereby moving the locomotive forward. FIG. 4 is a figure of the transmission case 40 and the actuator cover 58 as seen from the left side of the vehicle body. Referring to FIG. 4, the transmission case 40 and the actuator cover 58 are engaged with each other along an engaging portion i F . The engaging portion 1 F includes a sealing member (to be described later) provided on the engaging portion 1 F for waterproofly sealing the engaging portion 1 F. According to the detailed description below, the engaging portion 1 F is formed by a plane perpendicular to the graphic plane. The parts F and F1 of the transmission case 40 and the actuator cover 58 will form a coplanar surface, and the transmission case cover 401 is assembled to these parts, that is, it is assembled on this coplanar surface. … FIG. 5 is a front view of the actuator cover 58, and FIG. 6 is a cross-sectional view taken along line A-A of FIG. 5. The actuator cover 5 8 covers the parts of the reduction system from the motor -17- 200521020 (14) 57 to the shaft 64 as described above, and also serves as a cover for the water pump, wherein the water pump circulates cooling water through the engine. Referring to FIG. 5, a tubular protrusion 581 is formed on the actuator cover 58 to receive a worm gear 110 engaged with a gear 641 and a shaft 111 for the worm gear 110. The gear is mounted on a support plate 85. The bearing 70 is supported, and the protrusion can also support the shaft 1 1 1. A rotation sensor 1 1 2 for detecting the rotation position of the worm wheel 1 1 0 is connected to the shaft 1 1 1. The detection output of the rotation sensor 1 1 2 is supplied to a control device not shown. And, through the gears 641, 65, 66, and 531 that are connected to the worm wheel 1 10, the position of the movable pulley portion 452 is detected based on the output detection result. The actuator cover 58 has embossments 582, 583 for fixing the base plate 5 7 1 of the motor 57 and seats 5 8 5, 5 8 6, wherein these seats are arranged in a embossed hole 5 84 so as to receive the base plate 571 Of wheels. Moreover, it can be seen from FIG. 6 that the sensor cover 58 forms an outer wall of a water pump 113 and can cooperate with a part of the transmission case 40. A thruster Π 4 and a shaft 1 15 are contained in a space surrounded by the outer wall. The shaft 115 is connected to the engine by a transmission device not shown, and is driven by the rotation of the engine. One ring 1 1 6 is an inlet for cooling water circulated from the radiator through a thermostat, and the other ring 1 1 7 is an inlet for cooling water circulated without passing through the radiator. At the start of the engine or when the temperature of the cooling water is very low, water will enter through the mouth ring 1 1 7, but if the temperature of the cooling water is higher than a predetermined temperature, the cooled water will pass through the mouth ring U 6 Into the radiator. FIG. 7 is a plan view showing a seal placed between the transmission case 40 and the actuator cover -18- 200521020 (15) 5 8, and FIG. 8 is a side view showing the main part of the seal, and Figure 9 is the end of the seal. The seal 1 20 has: an annular portion 1 2 1 for waterproofly sealing the water pump 1 1 3; an elongated portion extending from one direction of the annular portion 1 2 1; and another elongated portion 1 23, The system extends from the other direction of the ring portion 1 2 1. The seal 1 2 0 is formed so as to be able to flex in a direction perpendicular to the graphic plane, so that a two-dimensional plane can be maintained. Along this seal, the transmission case 40 and the actuator cover 58 can be waterproofed to each other. Snap together. In other words, the portions 127 and 128 extending from the protrusions 124 and 125 to both sides of the tail end portion and the elongated portion 122 interposed between the protrusions 124 and 125 are different in shape from each other. In particular, although the portion 1 22 has a circular cross-section so that it can fit into a groove, the portions 1 2 7 and 1 2 8 on both sides of the tail portion from the protrusions 124 and 125 have such a three-dimensional shape, This allows them to wind one end surface of the actuator cover 58 (refer to FIGS. 8 and 9). In particular, the rear end portion of the seal 120 includes a box-shaped portion 128 that is opened along one surface so as to cover The end cover of the actuator cover 58 is also provided; and it also has a portion 129 for connecting the box-shaped portion 128 and the protrusion 124 to each other. A hook portion 128a is provided on one end of the box-shaped portion 128 and is wound around the end surface of the actuator cover 58. FIG. 10 is a rear view of the actuator, which is a figure of the actuator cover seen from the transmission case 40; and FIG. 11 is a cross-sectional view taken along line B-B of FIG. Referring to FIG. 10, a sealing groove for receiving the sealing member 120 is formed substantially along the outer contour of the actuator cover 58. Sealing groove -19- 200521020 (16) 1 3 0 has a ring-shaped groove 1 2 1 which is a ring-shaped portion which accommodates a sealing member: 2 2 and an elongated groove 1 3 2 extending from the ring-shaped groove 1 3 1. Moreover, two lead-out portions are formed, one of which is used to extend the seal 120 from the partial annular groove 1 3 1 to the outside, and the other lead-out portion 1 3 4 is used to extend the seal 1 2 0 extends from the elongated grooves 1 2 to the outside. In addition, circular recesses 1 35 and 1 36 for fixed seals are provided near the lead-out portions 1 33 and 1 3 4 respectively. Referring to FIGS. 10 and 11, the engaging portion between the transmission case 40 and the actuator cover 58 includes an inclined portion, which is a surface F3 (parallel to the above-mentioned F and F1) parallel to the front-rear direction of the vehicle body. Plane), and includes surfaces F4 and F5, which stand upright on the width of the vehicle from surface F3. The seals 120 indicated by dashed lines in Fig. 11 are placed along the surfaces F 3 and F 4 and F 5 and are fixed to the protrusions 124 and 125 in the middle of the circular recesses 135 and 136, respectively. Moreover, the hook portion 1 2 a at the one end portion of the seal 120 is captured by the groove surface 5 8 a at the one end surface of the actuator cover 5 8, and is directed to the transmission case cover 4 0 1 by In this way, in addition to the sealing mechanism, the transmission device of this embodiment is used to waterproofly seal the transmission case 40 and the transmission case cover 401 in addition to the sealing mechanism. It is used for dust-proof objects; it also includes a seal 1 2 0, which has an enhanced sealing effect in order to maintain waterproof performance. Thus, it is possible to provide a sealing condition suitable for a water pump between the actuator cover 58 and the transmission case 40, wherein the actuator cover and the transmission case are members of a wall surface of the water pump. Figures 12 and 13 show a second embodiment of the invention. In particular, as shown in Figure-20-200521020 (17) 12, a vehicle in the form of a locomotive includes a body frame F at the front end; a front fork 25, which can support the front wheel WF for rotation; and a head tube 27, which It is used to support a driver's handlebar 26, which is connected to the front fork 25 for driving operation. A unit swing engine UE is supported on a middle portion of the body frame F in the front-rear direction for rolling up and down, and a rear wheel WR for rotation is supported at one rear end thereof. A fuel tank 28, which is slender from top to bottom, and a radiator 29, which is placed behind the fuel tank 28, are arranged on the body frame F and in front of the unit swing engine UE. A storage box 30 is assembled to the body frame F, so that it can cover the unit swing engine from above, and the front and rear driving seats 31 are arranged on the storage box 30, and have a front seat 32 and a Back seat 33. Further, a vehicle body cover 34 made of synthetic resin is assembled to the vehicle body frame F, and covers the vehicle body frame F, a front portion of the unit swing engine UE, the radiator 29, and the storage box 30. Referring to FIG. 13, the unit swing engine UE includes an air-cooled engine E having a cylinder shaft extending substantially horizontally; and includes a belt-type variable transmission device M having a transmission belt and a pulley to move the engine e at a variable speed. The output power is transmitted to the rear wheel WR. The variable transmission device M can drive a movable pulley on the crank shaft side so as to change the transmission gear ratio corresponding to the operation of an electric motor 42 as an actuator. A transmission case 93 of the variable transmission device M is continuously provided on the left side of the crank case 44 of the engine E so that it will increase from the engine E to the left side and extend to the left side of the rear wheel WR. A swing arm 4 8 is connected to the right side of the crank phase 4 4 on one of the front vehicle parts and the rear wheel WR system is used for supporting -21-200521020 (18) to connect the swing arm 48 at the rear end of the transmission case 93 Rotate between the rear ends. Incidentally, an electric motor (actuator) 42 for changing the speed is placed on the left side of the cylinder 45 of the engine E and in front of the variable transmission device M, and is mounted on the forward protrusion 93a of the transmission case 93 So that its axis is oriented in the width direction of the car body. In addition, viewed from the side, the electric motor 42 is placed below a left passenger pedal 162 and interposed between a pair of left and right passenger pedals 162, and is disposed on the vehicle body cover 34 to form part of the vehicle body frame F. Between the two support frames 41 below the left support frame 41. Although the present invention has been described by the above embodiments, the invention can be changed in different ways. Such changes do not depart from the spirit and scope of the present invention, and for those skilled in the art, such modifications are covered within the scope defined by the scope of the following patent applications. [Brief description of the drawings] FIG. 1 is a sectional view showing a front portion of a belt type continuously variable transmission device according to a first embodiment of the present invention; FIG. 2 is a sectional view showing a belt type of a first embodiment of the present invention A rear part of the continuously variable transmission device; FIG. 3 is a side view showing a locomotive according to the first embodiment of the present invention; FIG. 4 is a front view showing a transmission case and an actuator cover; and FIG. 5 is a front view. A gear unit cover provided at the front of a continuously variable transmission device; FIG. 6 is a sectional view '-22- 200521020 (19) a wall portion of a water pump formed by an actuator cover and a transmission case; FIG. 7 is a plan view of a seal; FIG. 8 is a side view showing the main parts of the seal; FIG. 9 is an enlarged view showing one end of the seal; FIG. 10 is a rear view of the actuator cover; 11 is a cross-sectional view taken along line BB of FIG. 10; FIG. 12 is a left side view showing a self-propelled locomotive according to a second embodiment of the present invention; and FIG. Relative configuration between engine, continuously variable transmission equipment, and rear wheels Shape. [Description of main component symbols] 1: Locomotive 2: Front part of vehicle body 3: Rear part of vehicle body 4: Floor part 5: Head tube 6: Lower tube 7: Supervisor 8: Seat 1 1: Handlebar 1 2: Front fork I 3 : Front wheel 1 5: Bracket 23- 200521020 (20) 1 6: Link member 1 7: Swing unit 1 8: Hanging bracket 2 1: Rear wheel 22: Suspension mechanism 23: Intake pipe 24: Carburetor 26: Main frame 27: Kick shaft 2 8: Fuel tank 29: Radiator 3 0: Storage box 3 1: Crank case 32: Front seat 3 3: Rear seat 3 5: V-belt continuous variable transmission device 3 6: Outer Cover 3 8: Reduction gear 4 0: Gearbox 4 1: Crank shaft 4 2: Electric motor 4 3: Drive shaft 44: Guide tube 4 5: Drive pulley-24- 200521020 (21) 47: Guide hole 48: Guide pin 4 9: collar 5 0: bearing retaining ring 51: bearing 5 2: retaining ring 5 3: slide bar 5 4: feed ring 5 5: tubular member 5 6: bolt 5 7: motor 5 8: to Actuator cover 5 8 a: End face groove 5 9: Motor shaft 6 0: Gear system 6 2, 6 3: First stage gear 6 1, 6 4: Common shaft 6 5, 6 6: Second stage gear 67, 68, 69, 70: Bearing 7 1: Bolt 72: Adjustment plate 73: Driven pulley 74: Driven shaft 75, 76 77, 8]: Bearing-25- 200521020 (22) 7 8: Collar 79: Cup-shaped clutch plate 8 2, 8 3: Rutani 8 0, 8 6 '· Nut 8 5: Clutch plate support plate 8 7 : Clutch plate 8 8: pivot 8 9: embossed 90: arm 91: spring 92: coil spring 9 3: transmission case 9 3 a: forward projection 94: input power gear 9 5, 9 6: intermediate gear 9 7 : Final stage gear 98, 99, 102, 103: Bearing 1 00: V-belt 1 0 1: Output power shaft 105: Sensor board] 06: Magnetic sensor 1 1 0: Worm gear 1 η: Shaft 1 1 2: Rotary sensor-26- 200521020 (23) 1 1 3: Water pump 1 14: Thruster 1 1 5: Shaft 1 1 6, 1 1 7: Mouth ring 1 2 0: Seat 1 2 1: Ring Parts 1 2 2, 1 2 3: Slim parts 1 24, 1 25: Protrusions 127, 128, 129: Parts 1 2 8 a: Hook parts 1 3 0: Seal grooves 131: Ring grooves 1 3 2: Slender Grooves 1 33, 1 34: Lead-out portions 135, 136: Circular recesses 1 62: Left passenger pedal 2 00: Bow 丨 Engine 401: Transmission case cover 4 02 ·· Rib 403: Housing 4 5 1: Fixed pulley Section 45 2: Movable pulley section 4 5 3: Hub 4 8] ·· Head -27- 200521020 (24) 53 1: 571: 5 72: 5 8 1: 5 82, 5 84: 5 8 5, 591: 641: 73 1: 7 3 2: Gear plate casing tubular protrusion 5 8 3: Embossed embossed hole 5 8 6: Seat output power gear gear fixed pulley part is available Moving pulley part-28-